Gait Speed and Task Specificity in Predicting Lower-Limb Kinematics: A Deep Learning Approach Using Inertial Sensors

Mayo Clinic Proceedings. Digital health Pub Date : 2024-11-27 DOI:10.1016/j.mcpdig.2024.11.004

Vaibhav R. Shah MSc , Philippe C. Dixon PhD

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Abstract

Objective

To develop a deep learning framework to predict lower-limb joint kinematics from inertial measurement unit (IMU) data across multiple gait tasks (walking, jogging, and running) and evaluate the impact of dynamic time warping (DTW) on reducing prediction errors.

Patients and Methods

Data were collected from 18 participants fitted with IMUs and an optical motion capture system between May 25, 2023, and May 30, 2023. A long short-term memory autoencoder supervised regression model was developed. The model consisted of multiple long short-term memory and convolution layers. Acceleration and gyroscope data from the IMUs in 3 axes and their magnitude for the proximal and distal sensors of each joint (hip, knee, and ankle) were inputs to the model. Optical motion capture kinematics were considered ground truth and used as an output to train the prediction model.

Results

The deep learning models achieved a root-mean-square error of less than 6° for hip, knee, and ankle joint sagittal plane angles, with the ankle showing the lowest error (5.1°). Task-specific models reported enhanced performance during certain gait phases, such as knee flexion during running. The application of DTW significantly reduced root-mean-square error across all tasks by at least 3° to 4°. External validation of independent data confirmed the model’s generalizability.

Conclusion

Our findings underscore the potential of IMU-based deep learning models for joint kinematic predictions, offering a practical solution for remote and continuous biomechanical assessments in health care and sports science.

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步态速度和任务特异性预测下肢运动：一种使用惯性传感器的深度学习方法

目的开发一种深度学习框架，从惯性测量单元（IMU）数据中预测多种步态任务（步行、慢跑和跑步）的下肢关节运动学，并评估动态时间翘曲（DTW）对减少预测误差的影响。患者和方法在2023年5月25日至2023年5月30日期间，收集了18名配备imu和光学运动捕捉系统的参与者的数据。建立了一种长短时记忆自编码器监督回归模型。该模型由多个长短期记忆层和卷积层组成。将imu在3个轴上的加速度和陀螺仪数据以及每个关节（髋关节、膝关节和踝关节）近端和远端传感器的大小输入到模型中。光学运动捕捉运动学被认为是真实的，并作为输出来训练预测模型。结果深度学习模型对髋关节、膝关节和踝关节矢状面角度的均方根误差小于6°，其中踝关节的误差最小（5.1°）。特定任务模型报告了在某些步态阶段的增强表现，例如跑步时的膝关节屈曲。DTW的应用显著降低了所有任务的均方根误差至少3到4°。独立数据的外部验证证实了模型的可推广性。我们的研究结果强调了基于imu的深度学习模型在关节运动学预测方面的潜力，为医疗保健和运动科学中的远程和连续生物力学评估提供了实用的解决方案。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Mayo Clinic Proceedings. Digital health Medicine and Dentistry (General), Health Informatics, Public Health and Health Policy

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审稿时长

47 days